org.mozilla.javascript.NodeTransformer Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of rhino Show documentation
Show all versions of rhino Show documentation
Rhino is an open-source implementation of JavaScript written entirely in Java. It is typically
embedded into Java applications to provide scripting to end users.
/* -*- Mode: java; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
package org.mozilla.javascript;
import java.util.ArrayList;
import java.util.List;
import org.mozilla.javascript.ast.FunctionNode;
import org.mozilla.javascript.ast.Jump;
import org.mozilla.javascript.ast.Scope;
import org.mozilla.javascript.ast.ScriptNode;
/**
* This class transforms a tree to a lower-level representation for codegen.
*
* @see Node
* @author Norris Boyd
*/
public class NodeTransformer
{
public NodeTransformer()
{
}
public final void transform(ScriptNode tree, CompilerEnvirons env)
{
transform(tree, false, env);
}
public final void transform(ScriptNode tree, boolean inStrictMode, CompilerEnvirons env)
{
boolean useStrictMode = inStrictMode;
// Support strict mode inside a function only for "ES6" language level
// and above. Otherwise, we will end up breaking backward compatibility for
// many existing scripts.
if ((env.getLanguageVersion() >= Context.VERSION_ES6) && tree.isInStrictMode()) {
useStrictMode = true;
}
transformCompilationUnit(tree, useStrictMode);
for (int i = 0; i != tree.getFunctionCount(); ++i) {
FunctionNode fn = tree.getFunctionNode(i);
transform(fn, useStrictMode, env);
}
}
private void transformCompilationUnit(ScriptNode tree, boolean inStrictMode)
{
loops = new ObjArray();
loopEnds = new ObjArray();
// to save against upchecks if no finally blocks are used.
hasFinally = false;
// Flatten all only if we are not using scope objects for block scope
boolean createScopeObjects = tree.getType() != Token.FUNCTION ||
((FunctionNode)tree).requiresActivation();
tree.flattenSymbolTable(!createScopeObjects);
//uncomment to print tree before transformation
if (Token.printTrees) System.out.println(tree.toStringTree(tree));
transformCompilationUnit_r(tree, tree, tree, createScopeObjects,
inStrictMode);
}
private void transformCompilationUnit_r(final ScriptNode tree,
final Node parent,
Scope scope,
boolean createScopeObjects,
boolean inStrictMode)
{
Node node = null;
siblingLoop:
for (;;) {
Node previous = null;
if (node == null) {
node = parent.getFirstChild();
} else {
previous = node;
node = node.getNext();
}
if (node == null) {
break;
}
int type = node.getType();
if (createScopeObjects &&
(type == Token.BLOCK || type == Token.LOOP ||
type == Token.ARRAYCOMP) &&
(node instanceof Scope))
{
Scope newScope = (Scope) node;
if (newScope.getSymbolTable() != null) {
// transform to let statement so we get a with statement
// created to contain scoped let variables
Node let = new Node(type == Token.ARRAYCOMP ? Token.LETEXPR
: Token.LET);
Node innerLet = new Node(Token.LET);
let.addChildToBack(innerLet);
for (String name: newScope.getSymbolTable().keySet()) {
innerLet.addChildToBack(Node.newString(Token.NAME, name));
}
newScope.setSymbolTable(null); // so we don't transform again
Node oldNode = node;
node = replaceCurrent(parent, previous, node, let);
type = node.getType();
let.addChildToBack(oldNode);
}
}
switch (type) {
case Token.LABEL:
case Token.SWITCH:
case Token.LOOP:
loops.push(node);
loopEnds.push(((Jump)node).target);
break;
case Token.WITH:
{
loops.push(node);
Node leave = node.getNext();
if (leave.getType() != Token.LEAVEWITH) {
Kit.codeBug();
}
loopEnds.push(leave);
break;
}
case Token.TRY:
{
Jump jump = (Jump)node;
Node finallytarget = jump.getFinally();
if (finallytarget != null) {
hasFinally = true;
loops.push(node);
loopEnds.push(finallytarget);
}
break;
}
case Token.TARGET:
case Token.LEAVEWITH:
if (!loopEnds.isEmpty() && loopEnds.peek() == node) {
loopEnds.pop();
loops.pop();
}
break;
case Token.YIELD:
case Token.YIELD_STAR:
((FunctionNode)tree).addResumptionPoint(node);
break;
case Token.RETURN:
{
boolean isGenerator = tree.getType() == Token.FUNCTION
&& ((FunctionNode)tree).isGenerator();
if (isGenerator) {
node.putIntProp(Node.GENERATOR_END_PROP, 1);
}
/* If we didn't support try/finally, it wouldn't be
* necessary to put LEAVEWITH nodes here... but as
* we do need a series of JSR FINALLY nodes before
* each RETURN, we need to ensure that each finally
* block gets the correct scope... which could mean
* that some LEAVEWITH nodes are necessary.
*/
if (!hasFinally)
break; // skip the whole mess.
Node unwindBlock = null;
for (int i=loops.size()-1; i >= 0; i--) {
Node n = (Node) loops.get(i);
int elemtype = n.getType();
if (elemtype == Token.TRY || elemtype == Token.WITH) {
Node unwind;
if (elemtype == Token.TRY) {
Jump jsrnode = new Jump(Token.JSR);
Node jsrtarget = ((Jump)n).getFinally();
jsrnode.target = jsrtarget;
unwind = jsrnode;
} else {
unwind = new Node(Token.LEAVEWITH);
}
if (unwindBlock == null) {
unwindBlock = new Node(Token.BLOCK,
node.getLineno());
}
unwindBlock.addChildToBack(unwind);
}
}
if (unwindBlock != null) {
Node returnNode = node;
Node returnExpr = returnNode.getFirstChild();
node = replaceCurrent(parent, previous, node, unwindBlock);
if (returnExpr == null || isGenerator) {
unwindBlock.addChildToBack(returnNode);
} else {
Node store = new Node(Token.EXPR_RESULT, returnExpr);
unwindBlock.addChildToFront(store);
returnNode = new Node(Token.RETURN_RESULT);
unwindBlock.addChildToBack(returnNode);
// transform return expression
transformCompilationUnit_r(tree, store, scope,
createScopeObjects,
inStrictMode);
}
// skip transformCompilationUnit_r to avoid infinite loop
continue siblingLoop;
}
break;
}
case Token.BREAK:
case Token.CONTINUE:
{
Jump jump = (Jump)node;
Jump jumpStatement = jump.getJumpStatement();
if (jumpStatement == null) Kit.codeBug();
for (int i = loops.size(); ;) {
if (i == 0) {
// Parser/IRFactory ensure that break/continue
// always has a jump statement associated with it
// which should be found
throw Kit.codeBug();
}
--i;
Node n = (Node) loops.get(i);
if (n == jumpStatement) {
break;
}
int elemtype = n.getType();
if (elemtype == Token.WITH) {
Node leave = new Node(Token.LEAVEWITH);
previous = addBeforeCurrent(parent, previous, node,
leave);
} else if (elemtype == Token.TRY) {
Jump tryNode = (Jump)n;
Jump jsrFinally = new Jump(Token.JSR);
jsrFinally.target = tryNode.getFinally();
previous = addBeforeCurrent(parent, previous, node,
jsrFinally);
}
}
if (type == Token.BREAK) {
jump.target = jumpStatement.target;
} else {
jump.target = jumpStatement.getContinue();
}
jump.setType(Token.GOTO);
break;
}
case Token.CALL:
visitCall(node, tree);
break;
case Token.NEW:
visitNew(node, tree);
break;
case Token.LETEXPR:
case Token.LET: {
Node child = node.getFirstChild();
if (child.getType() == Token.LET) {
// We have a let statement or expression rather than a
// let declaration
boolean createWith = tree.getType() != Token.FUNCTION
|| ((FunctionNode)tree).requiresActivation();
node = visitLet(createWith, parent, previous, node);
break;
}
// fall through to process let declaration...
}
/* fall through */
case Token.CONST:
case Token.VAR:
{
Node result = new Node(Token.BLOCK);
for (Node cursor = node.getFirstChild(); cursor != null;) {
// Move cursor to next before createAssignment gets chance
// to change n.next
Node n = cursor;
cursor = cursor.getNext();
if (n.getType() == Token.NAME) {
if (!n.hasChildren())
continue;
Node init = n.getFirstChild();
n.removeChild(init);
n.setType(Token.BINDNAME);
n = new Node(type == Token.CONST ?
Token.SETCONST :
Token.SETNAME,
n, init);
} else {
// May be a destructuring assignment already transformed
// to a LETEXPR
if (n.getType() != Token.LETEXPR)
throw Kit.codeBug();
}
Node pop = new Node(Token.EXPR_VOID, n, node.getLineno());
result.addChildToBack(pop);
}
node = replaceCurrent(parent, previous, node, result);
break;
}
case Token.TYPEOFNAME: {
Scope defining = scope.getDefiningScope(node.getString());
if (defining != null) {
node.setScope(defining);
}
}
break;
case Token.TYPEOF:
case Token.IFNE: {
/* We want to suppress warnings for undefined property o.p
* for the following constructs: typeof o.p, if (o.p),
* if (!o.p), if (o.p == undefined), if (undefined == o.p)
*/
Node child = node.getFirstChild();
if (type == Token.IFNE) {
while (child.getType() == Token.NOT) {
child = child.getFirstChild();
}
if (child.getType() == Token.EQ ||
child.getType() == Token.NE) {
Node first = child.getFirstChild();
Node last = child.getLastChild();
if (first.getType() == Token.NAME &&
first.getString().equals("undefined")) {
child = last;
} else if (last.getType() == Token.NAME &&
last.getString().equals("undefined")) {
child = first;
}
}
}
if (child.getType() == Token.GETPROP) {
child.setType(Token.GETPROPNOWARN);
}
break;
}
case Token.SETNAME:
if (inStrictMode) {
node.setType(Token.STRICT_SETNAME);
}
/* fall through */
case Token.NAME:
case Token.SETCONST:
case Token.DELPROP:
{
// Turn name to var for faster access if possible
if (createScopeObjects) {
break;
}
Node nameSource;
if (type == Token.NAME) {
nameSource = node;
} else {
nameSource = node.getFirstChild();
if (nameSource.getType() != Token.BINDNAME) {
if (type == Token.DELPROP) {
break;
}
throw Kit.codeBug();
}
}
if (nameSource.getScope() != null) {
break; // already have a scope set
}
String name = nameSource.getString();
Scope defining = scope.getDefiningScope(name);
if (defining != null) {
nameSource.setScope(defining);
if (type == Token.NAME) {
node.setType(Token.GETVAR);
} else if (type == Token.SETNAME ||
type == Token.STRICT_SETNAME) {
node.setType(Token.SETVAR);
nameSource.setType(Token.STRING);
} else if (type == Token.SETCONST) {
node.setType(Token.SETCONSTVAR);
nameSource.setType(Token.STRING);
} else if (type == Token.DELPROP) {
// Local variables are by definition permanent
Node n = new Node(Token.FALSE);
node = replaceCurrent(parent, previous, node, n);
} else {
throw Kit.codeBug();
}
}
break;
}
}
transformCompilationUnit_r(tree, node,
node instanceof Scope ? (Scope)node : scope,
createScopeObjects, inStrictMode);
}
}
protected void visitNew(Node node, ScriptNode tree) {
}
protected void visitCall(Node node, ScriptNode tree) {
}
protected Node visitLet(boolean createWith, Node parent, Node previous,
Node scopeNode)
{
Node vars = scopeNode.getFirstChild();
Node body = vars.getNext();
scopeNode.removeChild(vars);
scopeNode.removeChild(body);
boolean isExpression = scopeNode.getType() == Token.LETEXPR;
Node result;
Node newVars;
if (createWith) {
result = new Node(isExpression ? Token.WITHEXPR : Token.BLOCK);
result = replaceCurrent(parent, previous, scopeNode, result);
ArrayList
© 2015 - 2024 Weber Informatics LLC | Privacy Policy